Rafael I. Monsalve

IgE-binding and histamine-release capabilities of the main carbohydrate component isolated from the major allergen of olive tree pollen, Ole e 1

BACKGROUND Pollen from olive trees (Olea europaea ) is a cause of pollinosis and an aggravating of asthma in Mediterranean regions. Recently, Ole e 1, the major allergen from olive tree pollen, has been isolated and its amino acid sequence has been elucidated. It is a glycoprotein whose carbohydrate moiety is involved in an IgE-binding epitope responsible for cross-reactivity among plant glycoproteins. However, the allergenicity of the free carbohydrate side chains remains to be clarified. OBJECTIVE The purpose of this study was to isolate the main carbohydrate component of Ole e 1 allergen and analyze its IgE-binding and histamine-release capabilities. METHODS Deglycosylation treatment of Ole e 1 with PNGase F and gel exclusion chromatography were used to isolate the main sugar component of the allergen. Sera of patients who are allergic to olive pollen and sera sensitive to Ole e 1 have been used in dot blotting assays of IgE binding to the isolated carbohydrate. Heparinized whole blood obtained from patients sensitive to Ole e 1 were stimulated by the free carbohydrate; the resulting histamine release was measured. RESULTS The main sugar component of Ole e 1 has been isolated. Free carbohydrate was able to bind IgE from sera of patients allergic to olive pollen; the sera of 65% of these patients contained anticarbohydrate reacting IgE, and 100% of those patients were sensitive to Ole e 1. The free carbohydrate promoted in vitro histamine release from basophils of sensitized patients. CONCLUSION The carbohydrate moieties of allergenic glycoproteins can constitute significant determinants on the binding to IgE of the sera from patients who are hypersensitive and can be responsible for inducing histamine release from blood cells.

Cross-reactivity between the major allergen from olive pollen and unrelated glycoproteins: Evidence of an epitope in the glycan moiety of the allergen ☆ ☆☆ ★ ★★

Ole e 1, the major allergen from olive pollen, is a glycoprotein containing a single Asn-linked glycan moiety. Rabbit antiserum against this protein has been obtained; and its immunologic cross-reactivities in Western blotting with ascorbate oxidase, horseradish peroxidase, bromelain, ovalbumin, and honeybee venom phospholipase A2 have been studied. Ascorbate oxidase, peroxidase, and bromelain are recognized by the Ole e 1 antiserum. When these three proteins are deglycosylated by periodate treatment, such an immunologic reaction does not occur. The relative affinities of these proteins have been analyzed by direct and inhibition ELISA experiments. A commercially available antibody against horseradish peroxidase has also been considered in these studies. This antibody reacts with Ole e 1 but not with the periodate-deglycosylated allergen. Horseradish peroxidase, bromelain, and ascorbate oxidase are recognized by the IgE of sera from patients who are hypersensitive to olive tree pollen. This binding is also abolished by periodate treatment. The results are interpreted in terms of the presence of an epitope in the carbohydrate moiety of Ole e 1, which would contain a xylose involved in recognition by both IgE and IgG antibodies.

The Spectrum of Olive Pollen Allergens

Olive pollen is one of the most important causes of seasonal respiratory allergy in Mediterranean countries, where this tree is intensely cultivated. Among the high number of protein allergens detected in this pollen, 8 – Ole e 1 to Ole e 8 – have been isolated and characterized. Ole e 1 is the most frequent sensitizing agent, affecting more than 70% of the patients suffering of olive pollinosis, although others, such as Ole e 4 and Ole e 7, have also been shown to be major allergens. In this context, the prevalence of many olive pollen allergens seems to be dependent on the geographical area where the sensitized patients live. Some of the olive allergens have been revealed as members of known protein families: profilin (Ole e 2), Ca2+-binding proteins (Ole e 3 and Ole e 8), superoxide dismutase (Ole e 5) and lipid transfer protein (Ole e 7). No biological function has been demonstrated for Ole e 1, whereas Ole e 4 and Ole e 6 are new proteins without homology to known sequences from databases. cDNAs encoding for Ole e 1, Ole e 3 and Ole e 8 have been overproduced in heterologous systems. The recombinant products were correctly folded and exhibited the functional activities of the natural allergens. In addition to the Oleaceae family, other species, such as Gramineae or Betulaceae, contain pollen allergens structurally or immunologically related to those of the olive tree. This fact allows to detect and evaluate antigenic cross-reactivities involving olive allergens. The aim of this research is the development of new diagnostic tools for olive pollinosis and new approaches to improve the classical immunotherapy.

Allergenic diversity of the olive pollen

A great number of allergenic proteins have been detected in olive pollen extracts. To date, nine allergens have been isolated and characterized, which have been called Ole e 1 to Ole e 9. The most prevalent olive allergen is Ole e 1, which affects more than 70% of patients hypersensitive to olive pollen, but others, such as Ole e 2, Ole e 8, and Ole e 9, have been demonstrated to be major allergens, and Ole e 6 or Ole e 7 reach high values of clinical incidence. Many of these allergens, such as Ole e 2 (profilin) and Ole e 3 (polcalcin), are involved in cross‐reactivities, which agrees with their adscription to panallergenic families. Among the many olive allergens of high molecular mass, only Ole e 9 (46 kDa) has been characterized. The allergen is a polymorphic and glycosylated β‐1,3‐glucanase, which belongs to a pathogenesis‐related (PR‐2) protein family. In addition to the polypeptide epitopes, Ole e 1 also exhibits IgE‐binding determinants in the carbohydrate, which are recognized by more than 60% of the sera from patients sensitive to the whole allergen, although the level of such glycan‐specific IgE seems not to be clinically relevant in the overall content of the sera. Recent advances in the elucidation of the structure of the Ole e 1‐oligosaccharide component allows us to explain the antigenicity of the molecule. Finally, the recombinant production of several allergens from olive pollen in both bacterial and eukaryotic cells has allowed us to resolve problems derived from the polymorphism and scarcity of the natural forms of these allergens. The biological equivalence between the natural and recombinant forms lets us initiate studies on the design of mixtures for clinical purposes, in which hypoallergenic derivatives of these allergens could play a definitive role.

Detection, isolation and complete amino acid sequence of an aeroallergenic protein from rapeseed flour

Background Seed proteins have been found to cause hypersensitivity by ingestion or inhalation. Rapeseed fiour was responsible for allergic symptoms in a patient, who develops into allergy to mustard spice.

Isolation of three allergenic fractions of the major allergen from Olea europea pollen and N-terminal amino acid sequence

A method to isolate the major allergen from olive pollen (Ole e I) in high yield is described. The allergenic fraction has been separated into 3 subfractions by reverse-phase HPLC. All these fractions were reactive to allergic sera from olive-sensitized patients, giving similar responses. No significant differences were observed between the amino acid compositions of these three proteins. The amino acid sequence of the first 27 amino acid residues from the N-terminal end is given. No homologies have been detected between Ole e I and other known allergens obtained from pollen.

Isolation and characterization of a major allergen from oriental mustard seeds, BrajI.

A 2 S albumin from oriental mustard (Brassica juncea) seeds has been isolated and characterized as an allergen. This protein, BrajI, was recognized by human IgE from mustard-sensitive individuals, as proved by using two different enzyme immunoassays. BrajI was found to be closely related to Sin a I, the major allergen from yellow mustard seeds. Many fractions with molecular weights ranging from 16,000 to 16,400 and with differences in charge were separated by ion-exchange chromatography. They exhibited small but significant amino acid composition differences for Glx, Val, Ile, Lys, and Arg contents. The heterogeneity of BrajI can be explained by size and charge differences of its heavy and light chains. All of the isoallergenic forms of BrajI gave a single precipitation band in double diffusion immunoassays when using a Sin a-I-specific rabbit polyclonal serum.

Isolation, cDNA cloning and expression of Lig v 1, the major allergen from privet pollen

Background An olive allergen‐like protein has been detected in privet pollen. This protein could be involved in the allergenic cross‐reactivity described for privet and olive tree pollen extracts.

Molecular and spectroscopic characterisation of a low molecular weight seed storage protein from yellow mustard (Sinapis alba L.)

Abstract 1. 1. A 1.7S protein has been purified from mustard seeds ( Sinapis alba L.). This protein, soluble in water and dilute salt solutions, is considered as an albumin and constitutes about 10% of the total soluble protein in mustard seeds. 2. 2. Its molecular weight is approximately 15,000 and is composed of two polypeptide chains (M r = 9500 and 5000), linked by two disulfide bridges. 3. 3. The amino acid compositions of both subunits as well as of the native protein are reported, showing a strong homology with napins from Brassica napus L. 4. 4. The ultraviolet absorption, fluorescence emission and circular dichroism spectra of the purified protein have been obtained. The mustard protein exhibits about 50% α-helix with a very low β-structure content. Based on its structural characteristics, a zein-like packing is proposed for this protein from mustard seeds.

A new distinct group of 2 S albumins from rapeseed: Amino acid sequence of two low molecular weight napins

Two napins (nIa and nIb), isolated from Brassica napus (rapeseed) seeds, have been sequenced. The two proteins show the common structural pattern of the 2 S albumins, since they are composed of two disulfide‐linked chains of different size, yet they exhibit an atypical low molecular weight (12.5 kDa vs. 14.5 kDa of the major napins). High sequence similarity has been found between these 2 proteins, but only 54% similarity can be estimated from their comparison with the 14.5 kDa major napins. Thus, nIa and nIb are considered representatives of a new distinct group of rapeseed napins since all the previously known napins exhibit 95% sequence similarity. Unexpectedly, the similarity increases when compared with the 2 S proteins from other species.